Abstract
Plant mutants with defects in intermediate enzymes of the tryptophan biosynthetic pathway often display a blue fluorescent phenotype. This phenotype results from the accumulation of the fluorescent tryptophan precursor anthranilate, the bulk of which is found in a glucose-conjugated form. To elucidate factors that control fluorescent tryptophan metabolites, we conducted a genetic screen for suppressors of blue fluorescence in the Arabidopsis trp1-100 mutant, which has a defect in the second enzymatic step of the tryptophan pathway. This screen yielded loss-of-function mutations in the UDP-glucosyltransferase gene UGT74F2. The bacterially expressed UGT74F2 enzyme catalyzed a conjugation reaction, with free anthranilate and UDP-glucose as substrates, that yielded the same fluorescent glucose ester compound as extracted from the trp1-100 mutant. These results indicate that sugar conjugation of anthranilate by UGT74F2 allows its stable accumulation in plant tissues. A highly related Arabidopsis enzyme UGT74F1 could also catalyze this reaction in vitro and could complement the ugt74F2 mutation when overexpressed in vivo. However, the UGT74F1 gene is expressed at a lower level than the UGT74F2 gene. Therefore, even though UGT74F1 and UGT74F2 have redundant conjugating activities toward anthranilate, UGT74F2 is the major source of this activity in the plant.
Highlights
The Arabidopsis genome encodes over 100 predicted UDPglucosyltransferase (UGT)1 genes (1)
The blue fluorescent phenotype of plants with defects in tryptophan pathway enzymes is a useful reporter for the flux of tryptophan metabolites and the regulation of tryptophan pathway genes
Loss of UGT74F2 function blocks the fluorescence of the trp1–100 mutant (Fig. 2), and there is no detectable free anthranilate in trp1–100 ugt74F2 double-mutant seedling extracts (Fig. 7B)
Summary
Mutant Isolation—The Columbia (Col) trp100 gl1–1 strain was mutagenized by ethyl methane sulfonate as previously described (7). For the trp100 mutation, we used primers TRP1100F 5Ј-GCTAAATGATCTTCGTCTGG-3Ј, and TRP1100R 5Ј-CCACTCCTAGTGCCTCTAGTACATCAGAG-3Ј, where the underlined base is mismatched with the genomic sequence This primer set amplifies a 114-bp fragment. The Col trp100 gl1–1 ugt74F2 splice junction mutation strain was used for transgene complementation experiments. This strain was transformed with four constructs: a UGT74F2 genomic clone, a UGT74F1 genomic clone, the UGT74F2 cDNA driven by the 35S promoter, and the UGT74F1 cDNA driven by the 35S promoter. The UGT74F2 genomic clone consisted of an EcoRV fragment extending from 2.3 kb upstream of the translational start codon to 0.5 kb downstream of the translational stop codon inserted in the filled-in KpnI site of the pBIN19 plant transformation vector (21). To estimate the upper limit of Km for the UGT74F2 enzyme, we assumed that the rate was 85% of Vmax at the lowest substrate concentration assayed (based on 15% error on individual measurements) and calculated Km
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